Diffusion-weighted Line-scan Echo-planar Spectroscopic Imaging Technique to Reduce Motion Artifacts in Metabolite Diffusion Imaging

Diffusion-weighted Line-scan Echo-planar Spectroscopic Imaging Technique to Reduce Motion Artifacts in Metabolite Diffusion Imaging

Metabolite diffusion is expected to provide more specific microstructural and functional information than water diffusion. However, highly accurate measurement techniques have still not been developed, especially for reducing motion artifacts caused by cardiac pulsation and respiration. We developed...

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Bibliographic Details
Published in:Magnetic Resonance in Medical Sciences Vol. 14; no. 1; pp. 43 - 50
Main Authors: BITO, Yoshitaka, HIRATA, Koji, EBISU, Toshihiko, KAWAI, Yuko, OTAKE, Yosuke, HIRATA, Satoshi, SHIRAI, Toru, SOUTOME, Yoshihisa, OCHI, Hisaaki, YAMAMOTO, Etsuji, UMEDA, Masahiro, HIGUCHI, Toshihiro, TANAKA, Chuzo
Format: Journal Article
Language:English
Published: Japan Japanese Society for Magnetic Resonance in Medicine 01-01-2015
Japan Science and Technology Agency
Subjects:
Animals
Brain - metabolism
diffusion
Diffusion Magnetic Resonance Imaging - methods
Echo-Planar Imaging - methods
Image Processing, Computer-Assisted
metabolite
Motion
motion artifact
Phantoms, Imaging
rat
Rats
spectroscopic imaging
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Summary:Metabolite diffusion is expected to provide more specific microstructural and functional information than water diffusion. However, highly accurate measurement techniques have still not been developed, especially for reducing motion artifacts caused by cardiac pulsation and respiration. We developed a diffusion-weighted line-scan echo-planar spectroscopic imaging (DW-LSEPSI) technique to reduce such motion artifacts in measuring diffusion-weighted images (DWI) of metabolites. Our technique uses line-scan and echo-planar techniques to reduce phase errors induced by such motion during diffusion time. The phase errors are corrected using residual water signals in water suppression for each acquisition and at each spatial pixel specified by combining the line-scan and echo-planar techniques. We apply this technique to a moving phantom and a rat brain in vivo to demonstrate the reduction of motion artifacts in DWI and apparent diffusion coefficient (ADC) maps of metabolites. DW-LSEPSI will be useful for investigating a cellular diffusion environment using metabolites as probes.
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content type line 23
ISSN:1347-3182
1880-2206
DOI:10.2463/mrms.2014-0024